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Issue
Korean Chemical Engineering Research,
Vol.45, No.5, 506-514, 2007
합성가스 연소 매체순환식 가스연소기 적용을 위한 최적 산소공여입자 선정
Selection of the Best Oxygen Carrier Particle for Syngas Fueled Chemical-Looping Combustor
류호정, 김지웅, 조완근, 박문희
합성가스 연소 매체순환식 가스연소기 적용을 위한 최적 산소공여입자를 선정하기 위해 네 가지 산소공여입자(NiO/bentonite, NiO/LaAl11O18, CoxOy/CoAl2O4, NiO/NiAl2O4)에 대해 환원반응기체로 모사 합성가스(H2, CO2, CO 각각 30, 10, 60%)를 사용하여 열중량 분석기(TGA)에서 환원반응특성 및 탄소침적특성을 측정 및 해석하였다. 환원반응온도가 증가함에 따라 최대전환율, 산소전달능력이 증가하였고 산소전달속도 측면에서 900 ℃가 합성가스 연소반응에 적합한 조건으로 나타났으며 높은 환원반응온도(≥800 ℃)에서는 네 가지 입자 모두에 대해 탄소침적현상이 나타나지 않았다. 네 가지 산소공여입자 중 NiO 계 산소공여입자가 CoO 계 산소공여입자에 비해 반응성이 높게 나타났으며 NiO/bentonite 입자가 산소전달속도, 탄소침적도 면에서 가장 좋은 반응성을 나타내었다. NiO/bentonite 입자에 포함된 금속산화물의 함량이 증가함에 따라 산소전달능력과 산소전달속도가 증가하는 것으로 나타나 금속산화물의 함량이 높은 산소공여입자가 매체순환식 가스연소기의 안정적인 조업에 유리한 것으로 나타났다.
To select the best oxygen carrier particle for syngas fueled chemical-looping combustor, the reduction reactivity and carbon deposition characteristics were determined in a thermogravimetric analyzer. Four kinds of oxygen carrier particles (NiO/bentonite, NiO/LaAl11O18, CoxOy /CoAl2O4, NiO/NiAl2O4) were tested with the simulated syngas (30% H2, 10% CO2, 60% CO) as a reduction gas. With each of these particles, the maximum conversion and oxygen transfer capacity increase with increasing the reduction temperature At the given experimental range, the optimum operating temperature to maximize oxygen transfer rate is found to be 900 ℃ and carbon deposition on the particles could avoid at the temperature above 800 ℃. Among four kinds of oxygen carrier particles, the NiO-based particles exhibits better reactivity than the CoO-based particle. Moreover, the NiO/bentonite particle produces the best reactivity based on the oxygen transfer rate and the degree of carbon deposition. The measured oxygen transfer rate increases as the metal oxide content in NiO/bentonite particle is increased thereby higher metal oxide contents could provide stable operation of chemical-looping combustor.
Keywords: Chemical-looping Combustion; Oxygen Carrier Particle; Nickel Oxide; Syngas
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[Cited By]
  1. Ryu HJ, Shun DW, Bae DH, Park MH, Korean Journal of Chemical Engineering, 26(2), 523, 2009
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